HU219834B - Reusable clamp structure with tolerance-compensating and method for compensating tolerance - Google Patents

Abstract

A clamp structure with a clamping band (11) which can be used, for example, to fixedly secure a hose on a nipple and which includes a tightening arrangement (16, 17) for tightening the clamp structure about the object to be fastened and a tolerance-compensating arrangement (30) for the entire tolerance range of the hose and nipple. The tolerance-compensating arrangement (30) is thereby formed by a slot-like opening (31) punched-out of the clamping band (11) which is of such width (w) and length (l) that the lateral clamping band portions (33a, 33b) left on both sides of the slot-like opening (31) provide tolerance compensation at the clamping forces specified by the customer, taking into consideration also the fact that the material of the lateral band portions is work-hardened by the punching-out operation of the tolerance-compensating opening. <MATH>

Description

The present invention relates to a tolerance equalization reusable hose clamp and a method for equalizing the tolerance of such a clamp. This open hose clamp is made of a longitudinal clamp with a material with low elastic extensibility. The clamping strap is provided with a tolerance compensating arrangement that compensates for dimensional tolerances in the assembly, such as a hose and tube coupling on which the hose is to be fastened. In particular, the invention relates to a so-called low profile or clampless hose clamp of the type described above.

Open, open hose clamps are known, for example, from the prior art of U.S. Patent No. 4,492,004 to the present applicant. Although the hose clamps described in the prior art patent, such as those cited above, have been a huge success in the trade, they are not always able to cover the full range of user-specified tolerances of the hose coupling and hose assembly. This results from the fact that the material of the clamping tape, such as the stainless steel commonly used for such clamping clamps, has relatively low elastic extensibility in the longitudinal direction and therefore does not allow for a fully satisfactory clamping effect over the entire tolerance range of the hose and pipe coupling.

The problem of balancing tolerance in hose clamps has long been recognized and various solutions have been proposed. British Patent No. 778,861, for example, proposes the use of one or more flexible, arc-shaped balancing portions. French Patent No. 2,470,275 proposes corrugations in the clamp. This feature is also found in U.S. Patent Nos. 4,308,648 and 4,919,682. In order to avoid leaks during the corrugations, the corrugations had to be covered with the full width of the inner tape portion. Following the recommendations of GB 1,064,048, European Patent EP 0 296 918 proposes the use of mutually offset corrugations on opposite sides of a central cut. These prior art solutions still left open the problem of providing an internal clamping surface without steps, recesses and discontinuities. In addition, the need to cover the corrugations with the full width of the inner band of the clamping tape has increased the cost since the length of the clamping band has to be increased. In addition, the corrugations also cause cost problems because of the desired length of the clamping band in the hose clamp.

Other proposals have been to increase the elastic extensibility of the clamp. For example, in U.S. Patent No. 1,705,895, the tape has zigzag cut-outs to provide a degree of elasticity to the tape. Other forms for similar purposes are disclosed in U.S. Pat. No. 4,910,832 and DE 30 18 363, as well as in U.S. Pat. No. 4,987,651, issued to the present applicant. According to these patents, the concave side band portions enclose an opening at least approximately twice concave.

A common feature of all these earlier proposals mentioned above is the fact that they require the movement of the belt sections not only in the direction of the tensile forces, i.e. in the longitudinal direction of the clamping belt, but also in the transverse direction when deformed with tensile forces.

The present invention is based on the recognition that satisfactory tolerance compensation can be achieved with an opening cut out of the clamping band, which may be a single clamp, or more than one clamp, which is located in the longitudinal direction of the clamping band. Side portions remain on either side of the aperture formed by punching or stamping, which exhibit reduced resistance to elongation in the longitudinal direction of the clamping band. The overall width of the or each adjacent orifice must be at least equal to the width of any other orifice in the clamp. The length of the opening can be easily determined. This will be discussed in more detail later.

The tolerance equalization arrangement of the present invention should take into account the fact that perforation or extraction of the aperture from the clamping band in a conventional manner will harden the material in the band portions remaining in the clamping band. Therefore, longitudinally extending apertures have been proposed for various purposes, such as modifying bendability, particularly in so-called self-tensioning hose clamps made of spring material to reduce the diameter of the hose clamp. This is disclosed in U.S. Patent No. 4,773,129. Longitudinal openings are also suggested to compensate for the imbalance in the hose clamp in this patent application2.

The prior art of U.S. Patent No. 4,998,326 to Applicant No. 219,834. However, according to the latter patent, the longitudinal cuts or slots were to be located within the area where the overlapping belt portions created an imbalance in order to compensate for the resulting excess weight within that area. In contrast, there is no such requirement for positioning the tolerance opening according to the present invention. According to the invention, the tolerance compensation opening may be located within the non-overlapping area of the clamping band, i.e. within the area of the non-overlapping clamping band extending from the mechanical connection to the hose clamp clamping member. In the case where the hose clamp includes elements to prevent stairs, recesses and continuity gaps in the internal clamping surface, the tolerance compensation arrangement is for the gaps and recesses and gaps in the internal clamping surface of the non-overlapping clamp is located between mechanical joints. In any case, in some other applications, the limitations on the position of the tolerance opening do not apply to the tolerance opening according to the invention, since this opening can be placed by the designer wherever tensioning forces occur in the clamping strap. The length and width of the tolerance opening according to the invention are thus determined by the required tolerance range that the hose clamp must provide for the expected clamping forces at full tension.

It is an object of the present invention to provide a compensated hose clamp that covers a complete range of user-specified tolerances for a pipe coupling and hose assembly.

This problem is solved by providing the hose clamp, which comprises a clamping band with overlapping end portions and elements for securing the hose clamp to another part, including elements for mechanically joining the overlapping band ends, which equalize the tolerances in one part and the other part. These tolerance compensating members operate in the area of the lateral belt portions separated by a slot-like opening and have a reduced belt width. This reduced ribbon width under tensile loads exhibits less resistance to elastic stretching compared to normal full-width hose clamps. According to the invention, the width of the slit orifice is at least equal to the width of any other orifice in the clamp and the slit orifice is defined such that the elongation of the lateral strips prior to reaching the yield point is at least as great as the outer circumference tolerance.

Preferably, the tolerance compensation member is provided with at least one opening extending longitudinally of the clamping band and leaving lateral strip portions on both sides thereof. The width of this orifice is at least substantially equal to the width of any other orifice in the clamp. The length of the orifice depends on the yield strength and tensile strength of the side strips.

The opening is preferably extruded from the clamping band, having substantially rectangular and preferably rounded end portions.

Preferably, the orifice is located in the non-overlapping area of the clamping band, in the area between the members that mechanically connect the overlapping end portions of the clamping band and the clamping members of the hose clamp.

Preferably, the members for mechanically joining the overlapping end portions are the hooks in one end portion and the holes in the other end portion and the auxiliary elements in the clamping portion. Auxiliary elements are provided to provide an internal clamping surface without recesses, steps and discontinuities. The auxiliary elements consist of a tongue-like projection at one end of the tape and a tongue-receiving element at the other end of the tape.

Preferably, the tapered sections are reduced by at least one opening in the clamping strip, which leaves lateral strip sections. The width of these side band sections is individually less than 30% of the normal band width of the clamp band.

Advantageously, the hose clamp is an open hose clamp and the hose clamp tensioning element does not substantially compensate.

Preferably, the hose clamp clamping member is provided with protrusions formed integrally with the clamping strip in its longitudinal direction. These protrusions are substantially complementary in shape and are disposed in the inner and outer ribbon end portions of the clamping band so that the protrusion in the inner ribbon end portion slides below the protrusion in the outer ribbon end portion.

The width of at least one of the holes for mechanical connection is substantially equal to the width of the tolerance opening. This hole is also located in the longitudinal direction of the clamping band, so that this hole also contributes to the tolerance of the hose clamp.

The object of the method of creating a tolerance equalization according to the invention is that

a) making a clamp test piece by punching a hole in the center of the clamp so that the remaining side strips harden,

b) determining the yield strength and tensile strength of the semi-hardened side strips of the test piece,

c) further determining the percentage specific elongation of the specimen at the yield stress and tensile strength,

d) calculating the length of the opening in the longitudinal direction, which provides a given tolerance compensation, under the specified percentage yield point, in the presence of the required tensile forces for a given fully tensioned hose clamp; and

HU 219 834 Β

e) extruding a slit opening of a length and width from the clamping strap such that the elongation of the lateral strap portions of the clamping strap prior to reaching the yield point is at least equal to the tolerance of the outer periphery of the desired component to be fastened.

In the steps of the method of making the clamping band elastically extensible, an elongated opening of length and width is extruded from the clamping band so that a predetermined tensile stress is exerted on the web sections remaining in the area of the elongated slit opening, before reaching the target, adjust to the expected tolerance for the outside diameter of the object to be clamped.

In a further step of the process, the cross-section of the hardened portions remaining at the slit orifice is determined by taking into account the yield stress of the hardened material of the clamp, the maximum tensile stress expected in the clamp and the elongation required to create the elongation equalization.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention, features and advantages of the present invention will be described in more detail with reference to the accompanying drawings, in which:

Fig. 1 is a plan view of a hose clamp without a flap type having a tolerance equalization arrangement according to the invention;

Figure 2 is a side view of the hose clamp of Figure 1, a

Fig. 3 is a cross-sectional view of a hose clamp assembled in accordance with the invention, perpendicular to the axial direction;

4a. and 4b. Fig. 4A is a view of a portion of a clamping strap having a tolerance equalization opening which schematically illustrates the behavior of a tolerance equalizing opening under tensioning forces in the clamping strap; and

Figure 5 is a graph depicting in mm the elongation of a 0.8 mm thick and 10 mm wide clamping test piece made of AISI 304 stainless steel with a tolerance opening of 4.8 mm wide and 50 mm as a function of load N .

In the drawings, like reference numerals are used throughout the various drawings, a hose clamp 10 of the present invention, similar to the prior art hose clamp described in U.S. Patent No. 5,191,684, is provided which includes a clamping band 11. Each clamping belt has an inner end portion 11a and an outer end portion 11b which overlap each other when assembled with the hose clamp 10. The flat clamp is made of material - 1 and

2 for mechanical closure of the hose clamp 10 in the flat, post-extruded state shown in FIG. 3, the mechanical joint comprises one or more deep-drawn, cold-formed retaining hooks 12a and 12b and a guide hook 13, which is a rectangle. They are connected to the shaped hole 14 and the oblong hole 15 respectively. The holding hook 12a and 12b, as well as the guide hook 13, can thus be formed as described in more detail in the prior art of US Patent 4,199,012 to the Applicant. In a preassembled, untensioned condition, a retaining hook 12a closer to the free end of the inner rib portion 11a engages the hole 14, a guide hook 13 engages an elongated hole 15, and a retaining hook 12b farther away from the free end portion of the inner rib portion 11a . When fully installed, in the tensioned state (Fig. 3), the retaining hook 12b engages the hole 14, while the adjacent retaining hook 12a now engages along the rim 15a of the hole 15, as described in U.S. Patent No. 5,191,684. To tighten the hose clamp 10 around the object to be fastened, there is a tool insert 16 in the outer tape end portion 11b and a tool insert 17 in the inner tape end portion 11a. The tool insertion elements 16 and 17 are formed by deep-stamped, extruded projections having a partially convex cross-section as described in U.S. Patent 5,191,684, previously mentioned. The tool positioning member 16 is thus an extruded longitudinal tunnel-like member having a relatively low bulging shape and provided with a tool positioning abutment surface 16a and a torque limiter and tool positioning abutment surface 16b. The tool insertion abutment surface 16b prevents the hose clamp 10 from being subjected to excessive torque as described in U.S. Patent No. 5,191,684. The tool positioning member 17 in the inner strip end portion 11a has only one tool positioning abutment surface 17a, and both height and width can be reduced circumferentially toward the free end of the inner strip portion 11a. The tool insertion member 17 therefore forms a piece with the inner strip end portion 11a, except for the portion which is within the area of the tool insertion abutment surface 17a which is extruded after the transverse cut in the inner rib portion 11a. The tool insertion member 17 has a relatively low projection in a cross-sectional manner similar to the tool insertion member 16. This projection is lower than that of the tool holder 16, so that the tool holder 17 may slide under the tool holder 16. The die inserting member 16 is extruded from the clamping strip 11 by cold-forming, after making two transverse cuts in the clamping strip all forming the abutment surfaces 16a and 16b. The shape and dimensions of the tool insert members 16 and 17 are thus the same as those described in U.S. Patent No. 5,191,684. The contents of this patent are incorporated herein by reference. The all-clamping belt has a semicircular opening 18 and 19 near the abutment surfaces 17a and 16a. The openings 18 and 19 allow any conventional and suitable structure,

EN 219 834 Β the tips of the tensioning tool (not shown) should protrude therein so that the effective contact surface of the tensioning tool is larger. The maximum width of the openings 18 and 19 is greater than the maximum width of the tool insert 16 and 17 so that the flat engaging surfaces of the jaws of the gripping tool engage not only the tool insert surfaces 16a and 17a but also the openings of the lateral strip portions. as described above in U.S. Patent No. 5,191,684.

In order to provide an internal clamping surface without recesses, steps, and discontinuities, the inner end portion 11a terminates in a tongue-like projection 21 which is configured to engage a tongue-receiving member. In the embodiment shown, the tongue-receiving element is a central part 22 of a stamped press. The strip portion 22 forms a tongue receptacle and is provided on its two sides with a side strip portion 23a and 23b. The lateral strip portion 23a and 23b thus passes into the normal outer width of the outer strip portion 11b at the first stepped strip portion 24a and 24b and displaces the lateral portion 23a and 23b radially along the second portion of the second portion while radially displacing the tongue portion 22 It passes through 25 strips into the normal strip as described in more detail in the previous US Patent 4,199,012 to the Applicant. Since the radial displacement provided by the strip sections 24a and 24b is approximately equal to the thickness of the clamping strip, it is ensured that the inner strip portion 11a cannot escape outwardly from the stepped strip portion 24a and 24b to the outer strip portion 11b.

According to the invention, the tolerance equalization section including the opening 30 serving as a tolerance equalization arrangement is a rectangular slot 31 having a rounded end portion 32a and 32b and having a lateral strip portion 33a and 33b substantially flattened on both sides. As shown in Figures 1 and 3, the tolerance compensation section including the opening 30 in the area between the overlapping strip end portions 11a and 11b, more particularly the mechanical coupling arrangement 12b of the non-overlapping clamping strip 11 comprises a holding hook 12, guide 13, hole 14 and 15 holes. is located between the hook and the tool insert 16. In the case of an arrangement of stairs, recesses and discontinuities in the inner clamping surface, in the case of an arrangement consisting of a strip 22, a strip 23a and 23b, a strip 24a and 24b and a strip 25, a tolerance compensating section including an opening 30b A buckle-like belt portion 22 is disposed between a stepped belt portion 25.

4a. and 4b. Figures 4 to 5 are schematic diagrams illustrating the operation of a tolerance compensation section comprising an opening 30 according to the invention. In Fig. 4a, the length "L" is the length of the compensating slit aperture 31 all in the unstretched, flat state of the clamping band. 4b. Fig. 4A shows the length "L" 'due to the tensioning forces acting on the all-clamping band. These forces cause elongation in the lateral strip portions 33a and 33b. 4b. In Figures 1 to 4, the clamp is again in a flat condition for comparison. Therefore, in FIG. and 4b. Figure 3 is not to scale and is for illustrative purposes only.

Typical dimensions of a particular size of hose clamp, which are given by way of example only and which can be varied, as known to those skilled in the art, are as follows:

The AISI 304 stainless steel clamp 11 has a "b" thickness of 0.8 mm and a "c" width of the clamp (Fig. 1) of 10 mm. The tongue-like projection 21 has a length "d" of 11 mm and the end of the full-width end portion 11a of the clamping strip 11 is inclined at an angle of 45 °. The 14 "holes have a width" e "of 4.8 mm and a length" f "

4.7mm. The tunnel-shaped tool insert 16 has a length "g" of 12.2 mm and a hole "15" of 15.9 mm. The distance "i" between the free end of the outer tape end portion 11b and the end surface 15a of the hole 15 closer to the free end of the outer tape end portion 11b, and the distance j between the stepped strip portion 24a and 24b and the hole 15 1 mm. The tongue-engaging, buckle-like strip 22 has a Jt ”length of 13 mm. The slot (1) of slot 31 (Fig. 1) has a length of 50 mm and the rounded end portions 32a, 32b are semicircular. The distance "m" between the end of the tongue protrusion 21 and the end of the aperture 19 against the tool insert surface 17a and the "n" distance 45 between the end of the tongue protrusion 21 and the first end hook 12a near the free end of the tongue protrusion 21, 6 mm. The distance "o" between the end of the tongue-like projection 21 and the end of the second hook 12b is 52.5 mm. The distance "p" between the end of the tongue-like projection 21 and the end of the slot-like aperture 31, which is closer to the free end of the inner end portion 11a, is 62 mm. The tongue-receiving buckle-like web portion 22 has a width "q" of 4.2 mm, a width "r" of the tongue-like projection 21 and a distance "s" between the end of the tongue-like projection 21 and the end of the guide hook 13. The maximum width of the tool insert 17 is about 3.8 mm. The width "w" of the slot-like aperture 31

4.8 mm, while the lateral widths of each of the lateral strip portions 33a and 33b are 2.6 mm. As the width "w" of the slot-like aperture 31 increases, the width of the lateral strip portions 33a and 33b decreases, thereby reducing their resistance to elastic stretching in the longitudinal direction of the clamping belt. The total length "a" (Fig. 2) can be chosen arbitrarily for a given nominal diameter of the hose clamp 10. For any given diameter size, only the dimensions given above are important. The apertures 18 and 19 have a radius of 4.5 mm and each may have a small portion beyond the semicircle which is located all along the longitudinal direction of the clamping band.

The length of the slot-like aperture 31 (1) is defined such that the elongation of the lateral strip portions 33a, 33b prior to reaching the yield point is at least as large as the outer circumference of the part, such as the hose end5.

EN 219 834 Β tolerance for which you want to use a clamp. The length (1) and the width "w" may be determined experimentally.

The foregoing dimensions are given by way of example only and may be varied, as known to those skilled in the art, to adapt to the specific design of the hose clamp 10. For example, depending on the width of the clamping strip 11, instead of a single central slit opening 31, two or more slotted openings 31 may be provided in the longitudinal direction of the clamping strip, provided that the total area of these slots is sufficient to produce the desired tolerance.

The length and width of the tolerance slot 31 can be easily determined empirically. To do this, only one test specimen should be made from the clamp tape material, having a hole of a certain width and length cut out, and then incrementally increasing the test specimen to a tensile force that is expected to be fully clamped. By measuring the increase in length (elongation) and recording the subsequent elastic recovery of the test specimen, the appropriate length and width of the slit aperture 31 for a given material can be determined over a short period of time by trial. Previous experience with a given substance will allow this procedure to be shortened. It should also be borne in mind that the hose clamp provided with such an opening must also meet all the leakage tests normally required for that hose clamp. If necessary, this can be achieved by compromising the width and length of the opening.

The following approach is more scientific. Take a stainless steel clip with a yield point of 345 MPa. At each end of the central portion of the clamping band 10 mm wide and 0.8 mm thick, a slot-like opening 4.8 mm wide, 54.8 mm long and 2.4 mm radius is cut out. Thus, a 2.6 mm side strip portion remains on each side of the slot-like aperture. This means that the remaining cross-sectional area of the clamping band (W * T) = 2 (2.6 * 0.8) = 4.16 mm ²

A nominal yield point of 345 MPa would ensure that the clamp strap would withstand a tensile stress of 1434 N (345 * 4.16) before reaching the yield point. However, the extrusion of the slit orifice from the clamping band hardens the material so that the yield point is increased. The elongation at the yield point will then be 1.4 mm, which means an increase in the diameter of the hose clamp about 0.5 mm without exceeding the yield point of the material of the clamp.

In a typical example, 304 AISI stainless steel hose clamps with a band width of 10 mm and a thickness of 0.8 mm have a raw material yield strength of 392 N / mm ² and a tensile strength of 654 N / mm ² .

The numerical value of the mechanical properties increases with the cold forming of the material, that is, the extrusion of the gap increases the yield strength and tensile strength as follows:

yield strength at slit 549 N / mm ² and tensile strength at 705 N / mm ² .

Therefore, in the case of a gap with a 2.6 mm strip on each side of the 4.8 mm slot:

(W * T) * 579 = 2408 N.

This corresponds to an elongation of 1.7 mm, as shown in Figure 5, in a diagram showing a typical load-elongation function of a test piece with a slit. The 1.7 mm elongation corresponds to a 1.7 / π increase in diameter without exceeding the yield point, i.e. an Δ diameter increase of about 0.54 mm.

When using the tensile strength gap (W * T) * 705 = 2934 N.

As shown in the diagram of Fig. 5, the elongation is 10.74 mm, which corresponds to a diameter equalization of 0.27 mm without exceeding the tensile strength.

The elongation is expressed as a percentage of the original chart length (L), which percentage remains constant.

In the present example, an elongation of 0.54 corresponds to a specific elongation of 3.4%. For example, for length L = 25 mm, diameter offset * 0.034 / π = 0.27 mm.

Although only one embodiment of the invention has been described and described, it is understood that the tolerance compensation arrangement of the invention is not limited to this embodiment, but may also be used in other types of hose clamps which require some tolerance compensation. The tolerance compensation arrangement of the present invention can be used, for example, in a typical so-called Oetiker hose clamp described and disclosed in the prior art of U.S. Patent No. 4,299,012 to the Applicant or disclosed and disclosed in U.S. Patent No. 5,339,496. It can also be used in the hose clamp described and disclosed in the Applicant's Patent Application Serial No. 08 / 163,530, issued December 9, 1993, entitled "Clamp with a saw-tooth locking arrangement". The contents of this application are incorporated herein by reference. In addition, although the mechanical hook consisting of the retaining hook 12, the guide hook 13, and the holes 14 and 15 are of the type disclosed and described in the prior application of US patent 4,299,012, the retaining hook 12 may also be replaced by the prior art of the present application. U.S. Patent No. 4,622,720, with a combined guide and support hook. Furthermore, any other known mechanical bond can be applied to the overlapping end portions of the tape. As mentioned above, the tensioning arrangement may be replaced by a so-called Oetiker tab comprising a reinforcing element such as that disclosed in the prior US Patent No. 3,475,793 to the Applicant, or by using a narrow, substantially rectangular recess as disclosed in the present application.

U.S. Patent No. 5,282,295 to U.S. Pat. Instead of a single recess, two substantially parallel reinforcing recesses may be used in the bridge portion extending to the same entire area as "Enhanced Ear Clamps" filed December 18, 1990, U.S. Patent No. 5,282,295, or Applicant Application No. 07 / 629,716. , The disclosure of which is incorporated herein by reference. In addition, the projection 21, strip 22, strip 23a and 23b, strip 24a and 24b, and strip 25 of the present invention used to provide an internal clamping surface without recesses, steps, and discontinuities can be formed by the prior art of U.S. Patent No. 4,315,348. U.S. Patent Nos. 4,237,584 or 6,6-11 to U.S. Pat. No. 4,237,584 or U.S. Pat. No. 5,283,931. . Thus, the invention is not limited to the specific embodiments described and illustrated and / or their dimensions described herein, but can also be applied to other modified hose clamps which raise similar problems. Therefore, the invention is not limited to the details presented and described herein, and may be variations and modifications within the scope of the appended claims.

Claims (11)

A hose clamp (10), openly formed from a longitudinally low elongation clamping band (11), having overlapping web end portions (11a, 11b), for mechanically connecting the overlapping web end portions (11a, 11b) and a hose clamp. (10) further comprising elements for tensioning a component, including a tolerance compensating section, comprising at least one longitudinal slot (31) in the clamping strip (11) as an arrangement for compensating for the outer diameter of said component, said slot (31) strip portions (33a, 33b) delimited by parallel lines on both sides, characterized in that the width (w) of the slot opening (31) is at least equal to the width of any other opening in the clamping strip (11) and the length of the slot opening (31) (1) is bounded wherein the elongation of the side belt portions (33a, 33b) prior to reaching the yield stress is at least as great as the tolerance of the outer circumference of said component. Hose clamp according to Claim 1, characterized in that the slot-like opening (31) is extruded from the clamping band (11). Hose clamp according to claim 1 or 2, characterized in that the slot-like opening (31) is substantially rectangular and has rounded end portions. 4. Hose clamp according to any one of claims 1 to 5, characterized in that the slot-like opening (31) in the non-overlapping area of the clamping belt (11) is mechanically connecting elements of the overlapping strip end portions (11a, 11b), for example holding hooks (12a, 12b), guide hook (13). ), holes (14, 15) - and the hose clamp clamping elements, such as tool insertion elements (16, 17). 5. Hose clamp according to any one of claims 1 to 3, characterized in that the elements for mechanical connection of the overlapping end portions (11a, 11b) are provided with hooks (12a, 12b) in one end end (11a) and holes (14, 15b) in the other end end (11b). ) and auxiliary elements in the clamping band (11), which are additional elements for providing an internal clamping surface without recesses, steps and discontinuities, including a tongue-shaped projection (21) at one end of the band (11a) and the other end of the band (11b) a belt portion (22) formed as a tongue receptacle. 6. Hose clamp according to any one of claims 1 to 3, characterized in that the width (w) of the reduced width belt sections (33a, 33b) is less than 30% of the width of the clamping belt (11). 7. A hose clamp according to any one of claims 1 to 3, characterized in that the tolerance compensation section comprising the opening (30) is formed by a single slit opening (31) in the longitudinal direction of the clamping belt (11). 8. Hose clamp according to any one of claims 1 to 3, characterized in that the clamping member (10) is formed by protrusions formed integrally with the clamp (11) in its longitudinal direction; these protrusions are complementary in shape and are disposed in the inner and outer ribbon end portions (11a, 11b) of the clamping belt so that the protrusion in the inner ribbon end portion (11a) can slip below the protrusion in the outer ribbon end portion (11b). 9. Hose clamp according to any one of claims 1 to 3, characterized in that the width (e) of at least one of said holes (14,15) is equal to the width (w) of the slot-like opening (31) and also extends longitudinally of the clamping belt (11). hose clamp (10) for equalizing tolerance. 10. A hose clamp according to any one of claims 1 to 3, characterized in that the tool insert elements (16,17) for tensioning the hose clamp (10) do not include tolerance compensation. A method for implementing tolerance compensation in the case of metal tensioning tensile stresses in a longitudinally low elastic stretching strap (11), characterized in that: forming a clamp test piece by extruding a slit aperture (31) in the central region thereof to harden the remaining lateral strip portions (33a, 33b), determining the yield strength and tensile strength of the semi-hardened lateral strip portions (33a, 33b) the percent elongation at tensile strength and the tensile strength, as a function of the specified percentage yield strength, is calculated from the longitudinal direction of the slit orifice (31). The length (1) which provides a certain tolerance for the required tensile forces for a given fully tensioned hose clamp is necessary, and a slot (1) and a width (w) of length (1) and width are extruded from the clamping belt (11). 31), 5, that the elongation of the lateral strip portions (33a, 33b) of the clamping strip (11) remaining adjacent the slit opening (31) is at least as great as the tolerance of the outer circumference of the desired fastening component.